KR100397353B1 - One-Tap Equalizer Bank for the Orthogonal Frequency Division Multiplexing System - Google Patents

Abstract

The present invention relates to an Orthogonal Frequency Division Multiplexing (OFDM) system, and more particularly, to a one-tap used for compensating for distortion of a signal caused by a multipath fading channel in an OFDM system. One-Tap) Equalizer bank relates to an equalizer bank that reduces the complexity of the structure.

The present invention provides a method for compensating for distortion of a subcarrier signal caused by a multipath fading channel using a one-tap equalizer bank in an ODF system, using equalizer tap values of other adjacent subcarriers using equalizer tap values of adjacent subcarriers. Calculate a small amount of computation to compensate for signal distortion while significantly reducing system complexity.

According to the present invention, since only the calculated tap value is used to calculate the tap value of the equalizer, it is applicable regardless of the algorithm used, so that it can be applied to all equalizer banks having various algorithms.

Description

Signal distortion compensation method of one-tap equalizer bank for OPDM system {One-Tap Equalizer Bank for the Orthogonal Frequency Division Multiplexing System}

The present invention relates to an Orthogonal Frequency Division Multiplexing (hereinafter, referred to as OFDM) system, and more particularly, a one-tap used for compensating for distortion of a signal caused by a multipath fading channel in an OFDM system. -Tap) Equalizer banks that reduce the complexity of the equalizer bank structure.

OFDM is a multi-carrier transmission scheme that efficiently uses bandwidth through overlapping orthogonal sub-carrier spectrums.In general, a single carrier transmission scheme converts high-speed data into low-speed parallel data as compared with serial high-speed data transmission. It is a transmission method that makes high-speed transmission easily by reducing interference of adjacent transmission symbols under a multipath channel.

In such an OFDM system, fading effects due to multi-channels appear only as distortion of a transmission signal, unlike a serial transmission method in which adjacent symbol interference occurs, and a distortion of a transmission signal due to multipath fading is a serial transmission method. It is relatively easy to compensate.

In the OFDM system, such signal distortion is usually compensated by two methods.

One is a differential modulation and demodulation method in which information of transmission data is transmitted in a difference between two consecutive symbols.

The differential modulation and demodulation method has an advantage that it can be easily implemented by coding and transmitting the transmission data using a memory and an appropriate operation, but has the disadvantage that an error of one symbol generates an error of two symbols and is weak to noise.

Another method used to overcome this drawback is the coherent modulation and demodulation method with a one-tap equalizer bank.

The interference modulation and demodulation method is more complicated in structure than the differential modulation and demodulation method, but has about twice the performance in performance.

Although the differential modulation and demodulation method with a one-tap equalizer has a complicated structure, the development of semiconductor design and integration technology has made it possible to realize the interference modulation and demodulation method with a complicated one-tap equalizer bank.

However, the number of one-tap equalizers required in the one-tap equalizer bank is equal to the number of subcarriers, so that the number of subcarriers used and the complexity of the algorithm for calculating the equalizer tap values increase. There is a problem that the design of the interference modulation and demodulation method is difficult, even impossible to implement.

The present invention is to solve the above problems of the prior art, in introducing an interference modulation and demodulation method having a one-tap equalizer bank in an OFDM system, it is possible to greatly reduce the complexity of the structure while maintaining the system performance The purpose of this paper is to propose a one-tap equalizer bank to facilitate system implementation.

In order to achieve the above object, the present invention obtains a tap value by simple calculation using similar characteristics of channels of adjacent subcarriers in an OFDM system, and predicts a channel by using interpolation from the adjacent tap values. It is possible to implement an interference modulation / demodulation scheme with a one-tap equalizer bank without increasing the complexity.

1 is a block diagram of a general OFDM system.

2 is an implementation diagram of linear interpolation according to the present invention.

3 is an implementation diagram of a one-tap equalizer bank according to the present invention.

FIG. 4 is a graph comparing bit error rates according to an embodiment of the present invention (LMS) according to a frequency offset.

5 is a graph illustrating a comparison of the bit error rate according to another embodiment of the present invention (RLS) and the prior art.

<Description of the symbols for the main parts of the drawings>

10: transmitter 20: channel

30: receiver 40: adder

50: multiplier 60: full adder

Hereinafter, the one-tap equalizer bank proposed in the OFDM system according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a typical system model of an OFDM system employing an interference modulation and demodulation scheme having a one-tap equalizer bank, and is largely composed of three parts: a transmitter 10, a channel 20, and a receiver 30.

Referring to FIG. 1, high-speed serial data symbols input to the transmitter 10 are first higher-order modulated by a Series / Parallel (S / P) converter, that is, converted into low-speed parallel data symbols, and then inverse fast fourier transform. Modulate subcarriers

The modulated data symbol is inserted with a guard interval and converted into an analog signal suitable for transmission.

In this case, the complex amplitude of the OFDM signal transmitted from the transmitter 10 is expressed by Equation 1.

here Is the number of subcarriers, Is a constant relative to the power of the signal, Is the length of the OFDM symbol including the guard interval, Is In the first time interval Data symbol transmitted by the first subcarrier, Is Frequency of the first subcarrier, Is the carrier frequency, Has amplitude 1 and length Indicates a square pulse.

The OFDM transmission signal represented by Equation 1 is transmitted to the receiver 30 through the multipath channel 20.

The channel 20 used in the present invention is a two-path channel 20 having a direct wave passing through one direct path and a reflected wave component representing a plurality of delay paths.

The impulse response of the channel 20 is expressed as in Equation 2.

here Is the attenuation coefficient of the delay path with Rayleigh distribution, Denotes the delay of the equal distribution smaller than the guard interval.

The receiver 30 receives the signal passing through the multipath channel 20, removes the guard interval inserted by the transmitter 10, and performs subcarrier demodulation by using a fast fourier transform (FFT).

Demodulated The subcarrier signal is represented by Equation 3 as a sum of a transmission signal distorted by multipath fading and white noise.

here Is a noise component due to white noise.

In Equation 3, the multipath channel 20 Representing the distortion of the first signal In phase It can be seen that.

If the frequency division space between subcarriers ( ) Is the delay time ( If it is significantly smaller than), the distortion of the signal in adjacent subcarriers will be given a similar value.

The present invention takes advantage of this feature that the distortion of a signal in adjacent subcarriers is given a similar value.

A one-tap equalizer bank is used to compensate for signal distortion in an OFDM system. The value of this one-tap equalizer bank is approximately given as the inverse of the value of the signal distortion on each subcarrier.

Similar distortion values of signals of adjacent subcarriers intuitively mean that the tap values of two adjacent one-tap equalizers are similar, and thus the equalizers of other adjacent subcarriers using the tap values of the equalizers in the adjacent subcarriers. The value can be calculated.

Many methods are available for calculating the tap values of other adjacent subcarriers from the tap values of adjacent subcarriers, but in the present invention, a simple interpolation method represented by Equation 4 is used to reduce the complexity. The tap value by interpolation is calculated as in Equation 5.

here Is The tap value of the equalizer in the first subcarrier.

As described above, by using the linear interpolation method, it is possible to easily obtain a desired subcarrier tap value from equalizer tap values of two adjacent subcarriers.

In addition, when the linear interpolation method is used, the linear interpolation method may be implemented using only one full adder 60 to reduce the complexity of the system.

2 is an implementation diagram of linear interpolation using one full adder.

In linear interpolation, addition is performed by the full adder 60, and division is implemented without increasing the complexity by using a wired shift operation that shifts the output of the full adder 60 to one bit right. It is possible.

Using the one-tap equalizer bank using linear interpolation, one-tap equalizers corresponding to about half of the number of subcarriers can be implemented using one full adder and one multiplier.

Therefore, the complexity of the receiver 30 can be greatly reduced compared to the conventional method using a complicated algorithm.

In addition, the algorithm described above is not related to the algorithm for calculating the tap value and can be applied to the equalizer bank using various algorithms because only the calculated tap values are used, thereby providing flexibility and convenience in implementing the system.

3 shows a portion of an equalizer bank of an OFDM receiver 30 using a one-tap equalizer bank in accordance with the present invention.

In Figure 3, to show how much the equalizer bank according to the present invention reduces the complexity, the LMS (Least Mean Square) algorithm is used to obtain the tap value by a relatively simple operation in the adjacent subcarrier.

Although a simple LMS algorithm is used in the conventional equalizer bank, an adder and a multiplier corresponding to twice the number of subcarriers are required, and the same number of memories as the number of subcarriers are needed to store tap values. In the case of an equalizer bank, an adder, a multiplier, and a memory corresponding to half of a subcarrier needing about 1.5 times the number of subcarriers are required.

Therefore, an adder, a multiplier and a memory corresponding to about half of the number of subcarriers can be reduced.

This means that an OFDM system using a fairly large number of subcarriers can be implemented more easily than a conventional one-tap equalizer bank.

4 and 5 illustrate the bit error rate (BER) of the OFDM system using the equalizer bank of the present invention and the conventional OFDM system through simulation.

Here, the number of subcarriers is assumed to be 128 and parameter values of a typical millimeter wave channel are used. ) Is a random variable with a Rayleigh distribution, ) Is used for random variables with a uniform distribution smaller than the guard interval.

4 shows a comparison of the bit error rate of the conventional method using the Least Mean Square (LMS) algorithm and the OFDM system using the present invention when the average of the attenuation coefficients is 0.25.

A commonly used value of bit error rate It can be seen that the present invention has a very low performance degradation compared to the conventional method.

However, considering the complexity of the one-tap equalizer bank, the OFDM system using the present invention is easier in design and implementation, and even if the frequency offset is 30 Khz, the performance of the system to which the present invention is applied is hardly reduced. As a result, when the present invention is applied to an OFDM system, the complexity of the system can be greatly reduced compared to the conventional method without significant performance degradation.

FIG. 5 shows the bit error rate of an OFDM system having a conventional equalizer bank using a recursive least square (RLS) algorithm and an OFDM system to which the present invention is applied.

Bit Error Rate It can be seen that the present invention has a very low performance degradation compared to the conventional method.

This proves the validity that the present invention can be applied not only to LMS but also to RLS algorithm and can be applied to various algorithms because it is irrelevant to the calculation algorithm of tap value.

In addition, when the average values of the attenuation coefficients are 0.2 and 0.25, the performance of the OFDM system using the present invention is also similar to that of the conventional OFDM system.

This proves the validity that the present invention can be used in various channel conditions.

As described above, in the OFDM system, the one-tap equalizer bank according to the present invention simplifies the structure by enabling one-tap equalizers corresponding to about half of the number of subcarriers by using simple interpolation. Performance did not cause significant losses compared to conventional one-tap equalizer banks.

In addition, since the structure of the one-tap equalizer can be applied regardless of the algorithm used to calculate the tap value of the equalizer, the one-tap equalizer can be applied to an equalizer bank having various algorithms. This has the effect of providing flexibility.

Claims (4)

ODFM system that compensates for distortion of subcarrier signal by multipath fading channel using one-tap equalizer bank by calculating equalizer tap values of other adjacent subcarriers using equalizer tap values of adjacent subcarriers. A signal distortion compensation method of a one-tap equalizer bank; And a tap value of the equalizer is represented by Equation (6). here Is Tap value of the equalizer on the first subcarrier. delete The method of claim 1, wherein the tap value of the equalizer is calculated by a linear interpolation method represented by Equation (7). . 4. The signal distortion of the one-tap equalizer bank according to claim 3, wherein in the linear interpolation, addition is performed by a full adder and division is performed by a wired shift operation for shifting the output of the full adder by one bit to the right. Compensation Method.